CMD: A Database to Store the Bonding States of Cysteine Motifs with Secondary Structures

Overview

Journal Adv Bioinformatics

Specialty Biology

Date 2012 Oct 24

PMID 23091487

Citations 1

Authors

Hamed Bostan

Naomie Salim

Zeti Azura Hussein

Peter Klappa

Mohd Shahir Shamsir

Affiliations

Soon will be listed here.

Abstract

Computational approaches to the disulphide bonding state and its connectivity pattern prediction are based on various descriptors. One descriptor is the amino acid sequence motifs flanking the cysteine residue motifs. Despite the existence of disulphide bonding information in many databases and applications, there is no complete reference and motif query available at the moment. Cysteine motif database (CMD) is the first online resource that stores all cysteine residues, their flanking motifs with their secondary structure, and propensity values assignment derived from the laboratory data. We extracted more than 3 million cysteine motifs from PDB and UniProt data, annotated with secondary structure assignment, propensity value assignment, and frequency of occurrence and coefficiency of their bonding status. Removal of redundancies generated 15875 unique flanking motifs that are always bonded and 41577 unique patterns that are always nonbonded. Queries are based on the protein ID, FASTA sequence, sequence motif, and secondary structure individually or in batch format using the provided APIs that allow remote users to query our database via third party software and/or high throughput screening/querying. The CMD offers extensive information about the bonded, free cysteine residues, and their motifs that allows in-depth characterization of the sequence motif composition.

Citing Articles

Origin of anti-tumor activity of the cysteine-containing GO peptides and further optimization of their cytotoxic properties.

Tyuryaeva I, Lyublinskaya O, Podkorytov I, Skrynnikov N Sci Rep. 2017; 7:40217.

PMID: 28091523 PMC: 5238392. DOI: 10.1038/srep40217.

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